Journal
CURRENT BIOLOGY
Volume 25, Issue 7, Pages 928-935Publisher
CELL PRESS
DOI: 10.1016/j.cub.2015.01.067
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Funding
- Excellence Initiative of the German Federal Government [EXC 294 BIOSS]
- Excellence Initiative of the German State Government [EXC 294 BIOSS]
- NIH [R01GM059138]
- Swedish Research Council VR [621-2011-6004]
- Swedish Strategic Research Foundation
- Spanish Ministerio de Economia y Competitividad [BFU2011-28815]
- Marie Curie Career Integration Grant of the European Union (FP7-PEOPLE- CIG) [303674-Regopoc]
- King Abdullah Institute for Nano-technology (KAINS), King Saud University, Riyadh, Saudi Arabia
- DFG [HE 1640/23-1]
- Grants-in-Aid for Scientific Research [25113009, 25114510, 24580140] Funding Source: KAKEN
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During the transition from water to land, plants had to cope with the loss of water through transpiration, the inevitable result of photosynthetic CO2 fixation on land [1, 2]. Control of transpiration became possible through the development of a new cell type: guard cells, which form stomata. In vascular plants, stomatal regulation is mediated by the stress hormone ABA, which triggers the opening of the SnR kinase OST1-activated anion channel SLAC1 [3, 4]. To understand the evolution of this regulatory circuit, we cloned both ABA-signaling elements, SLAC1 and OST1, from a charophyte alga, a liverwort, and a moss, and functionally analyzed the channel-kinase interactions. We were able to show that the emergence of stomata in the last common ancestor of mosses and vascular plants coincided with the origin of SLAC1-type channels capable of using the ancient ABA drought signaling kinase OST1 for regulation of stomatal closure.
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